Method for removing U-shaped winding elements for an electromagnetically excitable core of an electric rotation machine from a setting tool

ABSTRACT

Method for removing U-shaped winding elements ( 10 ) for an electromagnetically excitable core ( 11 ) of an electric rotation machine ( 12 ) from a setting tool ( 20 ), wherein the U-shaped winding elements ( 10 ) are set and are initially located in the setting tool ( 20 ), wherein in one step the winding elements ( 10 ) are partially lifted out from the setting tool ( 20 ), so that parts of rod sections ( 13, 15 ) of the winding elements ( 10 ) are freely accessible from the outside, characterized in that the winding elements ( 10 ) are removed from the setting tool ( 20 ) by means of a removal device ( 75 ), by gripping the rod sections ( 13, 15 ).

BACKGROUND OF THE INVENTION

Methods for removing at least one U-shaped winding element for an electromagnetically excitable core of an electric rotation machine from a setting tool are known from the prior art. In that context, the U-shaped winding elements are pulled out individually from the recesses of the tool. This is therefore very time-consuming.

SUMMARY OF THE INVENTION

The object in the context of this application is to make a proposal for considerably quicker removal.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a U-shaped winding element,

FIG. 2 is a detail plan view of a setting tool,

FIG. 3 shows how winding elements are inserted into a pair of recesses of the setting tool,

FIG. 4 shows details of the shape of a winding element,

FIG. 5 shows how a gripping element with the tooth and the corner thereof presses an engagement contour into the rod section by shaping the rod section and thereby the tooth grips the rod section in a form-fitting manner with an engagement force,

FIG. 6 shows how, prior to the tooth gripping the rod section, the rod section is pressed radially inward by the sliding bevel,

FIG. 7 shows how over-setting is carried out with the setting tool,

FIG. 8 shows a certain position of the setting tool,

FIGS. 9a, 9b and 9c show, schematically, part of a procedure for removing the winding elements from the setting tool,

FIG. 10 shows a detail representation of two rod sections and two rod sections,

FIG. 11 shows how a lower flank of the slotted guide presses the slider between the (in this case four) rod sections,

FIG. 12 shows a method step in which the slider element first exerts a force in the radial direction on a winding element or an outer rod section,

FIG. 13 shows how the slider element is pushed from behind the slider element,

FIG. 14 shows how the clamping force between the two winding elements or the rod sections thereof is produced as a consequence of the slider element moving by sliding along the bevels,

FIGS. 15a, 15b, 15c and 15d show, schematically, the procedures for removing the winding elements from the setting tool and for insertion into an electromagnetically excitable core.

FIG. 16 is a schematic view of a U-shaped winding element for an electromagnetically excitable core of an electric rotation machine.

DETAILED DESCRIPTION

FIG. 1 shows a U-shaped winding element 10, as is used for example for the production of armatures (rotors) of direct-current motors or also for the production of armatures (stators) of alternating-current machines, such as three-phase generators. This U-shaped winding element 10 has a first rod section 13 and a second rod section 15 which are connected by an arcuate connection section 16. If the armature, to be constructed, of a rotor has for example 25 grooves, then 25 such winding elements 10 must be used. Also known are for example armatures of rotors having 17 or 19 or another number of winding elements 10.

FIG. 2 shows a detail plan view of a setting tool 20. This setting tool 20 has an inner tool part 23 and an outer tool part 26. Both the inner tool part 23 and the outer tool part 26 each have 25 groove-like recesses 29 and, respectively, 30, which for example may also be embodied in the manner of a tube. In a starting position of the two tool parts 23 and 26, the recesses 29 and 30 are positioned directly opposite one another such that they have essentially or entirely the same angular position with respect to a common, imaginary line 33 through an axis of rotation 36. The recesses 29 and 30 each have a side wall 39 and, respectively, 42 which in this case are reference surfaces. That is to say that the recesses 29 and 30 are oriented with respect to one another such that the side walls 39 and 42 preferably lie in a common plane. The winding elements 10 sit with their ends 41, 43 on a stop element (which is not shown here and which, for example, can be the slider 69 in FIG. 9a ), so as to give a minimum overlap between the arcuate connection section 16 and parts of the first rod section 13 and of the second rod section 15. This overlap allows the winding element 10 to be set.

FIG. 3 shows how winding elements 10 are inserted into a pair of recesses 29 and 30. It is in principle immaterial whether the winding elements 10 are used pre-set as shown in FIG. 3 or not pre-set. In this context, pre-set means that, in the starting position prior to rotation, a winding element 10 is inserted into recesses 29 and 30 which are not arranged directly opposite one another but offset with respect to one another. The winding element 10 has in this case an outer rod section 15 with a round wire cross section and an inner rod section 13 with two mutually parallel side faces 44 and 45 which are connected by rounds, see FIG. 4.

Furthermore, the setting tool 20 is provided with a gripping element 50. This gripping element 50 has at least one tooth 53. The gripping element 50 is preferably of arcuate construction and has, on an inner arc, for example eight teeth. Over the circumference of the outer tool part 26, there are provided in total preferably three preferably arcuate gripping elements 50. The other gripping elements have in this case preferably eight teeth in the case of one and nine teeth in the case of the other, such that all three gripping elements 50 overall preferably have 25 teeth 53. Thus, preferably, multiple gripping elements 50 with preferably in each case multiple teeth 53 are provided for use. It is thus possible for all 25 winding elements 10 to be gripped preferably simultaneously by the teeth 53.

Accordingly, there is provided a method according to which at least one U-shaped winding element 10 for an electromagnetically excitable core 11 of an electric rotation machine 12 is formed, wherein the U-shaped winding element 10 has a first rod section 13 and a second rod section 15 which are connected by an arcuate connection section 16, wherein an inner tool part 23 having at least one recess 29 in the region of its outer circumference is provided, and an outer tool part 26 having at least one recess 30 in the region of its inner circumference is provided, and at least the U-shaped winding element 10 is inserted into the inner tool part 23 and the outer tool part 26 such that one rod section 13 is inserted into a recess 29 of the inner tool part 23, the other rod section 15 is inserted into a recess 30 of the outer tool part 26, and such that the inner tool part 23 and the outer tool part 26 are rotated with respect to one another about the axis of rotation 36, wherein in that context the at least two rod sections 13, 15 of the at least one winding element 10 are moved away from one another, wherein, prior to the at least two rod sections 13, 15 being moved away from one another, a gripping element 50 having a tooth 53 is moved toward a rod section 15, which is gripped by means of a tooth 53.

In a further step, it is provided that the gripping element 50 with the tooth 53 and the corner 54 thereof presses an engagement contour 60 into the rod section 15 by shaping the rod section 15 and thereby the tooth 53 grips the rod section 15 in a form-fitting manner with an engagement force FE, see FIG. 5.

It is in particular provided that a tooth 53, when the tooth 53 is moved toward the rod section 15, exerts by means of a sliding bevel 63 a pressing force FP on the rod section 15 which, in conjunction with the recess 30 of the outer tool part 26, exerts a resulting force Fi radially inward. Thus, prior to the tooth 53 gripping the rod section 15, the rod section 15 is pressed by the sliding bevel 63 radially inward, see FIG. 6. If the rod section 15 is thereby pressed against a radial inner bearing surface 66 of the recess 30, the engagement contour 60 would preferably be produced thereafter (FIG. 5). In this procedure, the rod section 15 is then pressed against the recess 30.

It is provided that the gripping element 50 or the gripping elements 50 are driven in the direction of rotation. In that context, it is in particular provided that the one or more driven gripping elements 50 drive the outer tool part 26 in the direction of rotation by means of a stop element—preferably after passing through a free path. In that context, the two rod sections 13, 15 of a winding element 10 are in this case rotated further away from one another by for example at least five recesses 29 or, respectively, 30. Indeed, somewhat more rotation is effected, for example by an equalizing angle α of approximately 5°, in order to compensate for an elastic portion when bending the arcuate connection section 16 (“over-setting”), see FIG. 7. Preferably, after over-setting, the outer tool part 26 is rotated back by the equalizing angle α of approximately 5° in order to arrive at a so-called final position of the outer tool part 26. In this position of the outer tool part 26, the one or more gripping elements 50 are moved back to the point that the one or more teeth 53 disengage from the rod section 15 and its engagement contour 60, see FIG. 8.

Subsequently, the winding elements 10 can be removed from the setting tool 20. This is represented schematically in FIGS. 9a, 9b and 9c . As shown in FIG. 9a , a slider 69 presses the winding elements 10 from the side of their ends 41, 43 from the recesses 29 of the inner tool part 23 and the recesses 30 of the outer tool part 26 of the setting tool 20, such that the winding elements 10 are partially lifted out.

After this partial lifting out of the winding elements 10, those parts—in this case the upper parts—of the rod sections 13, 15 which are closest to the set, arcuate connection sections 16 are freely accessible from their side or from the side of the setting tool 20, such that a removal device 75 can remove the winding elements 10 from the setting tool 20 by gripping the rod sections 13, 15, see FIG. 9 c.

For removing the winding elements 10, sliders 70 are pushed between multiple winding elements 10 such that clamping forces FK are exerted between the winding elements 10 and the sliders 70 in the circumferential direction such that a winding element 10 is clamped between slider elements 78 and 79.

FIG. 10 shows a detail representation of two rod sections 13 and two rod sections 15, a single guide 80 with a single slider 70, a slotted disk 83 with a slotted guide 85 for the slider 70 and its guide peg 87. The slider 70 also has the already-mentioned slider elements 78 and 79. The slider element 78 is able to move in the guide 80 in the radial direction. This slider element 78 is driven by the slotted disk 83 rotating about the axis of rotation 36, such that the slotted guide 85 thereof moves in the circumferential direction U. In order to push the slider 70 between multiple winding elements 10, the slotted disk 83 rotates clockwise (circumferential direction U). A lower flank 90 of the slotted guide 85 presses the slider 70 between the (in this case four) rod sections 13, 15, see FIG. 11. The slider element 79 is also pushed, via a guide peg 91, by a slotted disk (not shown here) by means of a slotted guide (also not shown here) at first simultaneously and at the same speed into the wedge-shaped interspace 93. The slider elements 78 and 79 are thus pushed together between the winding elements 10. For the purpose of effecting the clamping force FK in the circumferential direction, the slider element 78 is pushed into the wedge-shaped interspace 93 between the slider element 79 and a winding element 10.

FIG. 12 shows the method step in which the slider element 79 first exerts a force FR in the radial direction on a winding element 10 or an outer rod section 15. In that context, the rod section 15 is pressed against the inner rim of the recess 30. The slider element 79 is now no longer pushed further radially inward. A cheek 95 is spaced apart a bit further in the circumferential direction with respect to the closest adjacent rod section 13 and thus does not yet exert a force in the circumferential direction on the rod section 13. On the rear side of the cheek 95 there is a bevel 98. The slider element 78 also has a cheek 99 and on the rear side of the cheek 99 there is a bevel 100. The slider element 79 thus first exerts the force FR in the radial direction and then the clamping force FK in the circumferential direction.

In the continuation of the method, FIG. 13, the slider element 78 is pushed from behind the slider element 79. In that context, the bevel 100 of the slider element 78 presses with increased force against the bevel 98 of the slider element 79, such that the force FR is increased. Together with the movement of the slider element 78, the sliding along the bevels 98 and 100 produces the clamping force FK between the two winding elements 10 or the rod sections 13 thereof, see FIG. 14. The two bevels 98 and 100 are then in a common oblique plane 103, which is not oriented radially with respect to the axis of rotation. One clamping force FK is then transmitted via the cheek 95 to the upper rod section 13 and the other clamping force FK is transmitted via the cheek 99 to the lower rod section 13. Thus, for removing the winding elements 10, sliders 70 are pushed between multiple winding elements 10 such that clamping forces FK are exerted in the circumferential direction between winding elements 10 and sliders 70 such that a winding element 10 or its rod section 13 is clamped between slider elements 78 and 79.

FIGS. 15a, 15b, 15c and 15d show method steps according to which, between all immediately adjacent rod sections 13, 15 which are arranged in a circumferentially adjacent recess 29 of an inner tool part 23 or in a recess 30 of an outer tool part 26 with a constant separation with respect to an axis of rotation 36, in each case one slider 70 simultaneously effects a clamping force FK on the immediately adjacent rod sections 13, 15 (FIG. 15a ) and thereby an entirety of all the winding elements 10 against one another are removed from the setting tool 20 via the intermediary of the sliders 70 (FIG. 15b ) and are then inserted into grooves (not shown) of an electromagnetically excitable core 11, FIGS. 15c and 15d . The core 11 can in this case be a body of a rotor with radially outward open grooves of an electric direct-current machine such as a starter for an internal combustion engine or also for example a stator with radially inward open grooves for an alternating-current generator, see FIG. 16. 

1. A method for removing U-shaped winding elements (10) for an electromagnetically excitable core (11) of an electric rotation machine (12) from a setting tool (20), wherein the U-shaped winding elements (10) are set and are initially located in the setting tool (20), wherein in one step the winding elements (10) are partially lifted out from the setting tool (20), so that parts of rod sections (13, 15) of the winding elements (10) are freely accessible from the outside, characterized in that the winding elements (10) are removed from the setting tool (20) by means of a removal device (75), by gripping the rod sections (13, 15).
 2. The method according to claim 1, characterized in that, for removing the winding elements (10), sliders (70) are pushed between multiple winding elements (10) such that clamping forces (FK) are exerted between the winding elements (10) and the sliders (70) in a circumferential direction such that a winding element (10) is clamped between slider elements (78) and (79).
 3. The method according to claim 2, characterized in that the slider elements (78, 79) are pushed together between the winding elements (10).
 4. The method according to claim 2, characterized in that the sliders (70) are pushed between multiple winding elements (10) by a rotatable slotted guide.
 5. The method according to claim 2, characterized in that one of the slider elements (79) exerts both a clamping force (FK) in the circumferential direction on a winding element (10) and a radial force (FR) in a radial direction on a winding element (10).
 6. The method according to claim 5, characterized in that the one of the slider elements (79) first exerts the radial force (FR) in the radial direction and then exerts the clamping force (FK) in the circumferential direction.
 7. The method according to claim 5, characterized in that, for the purpose of effecting the clamping force (FK) in the circumferential direction, the slider element (78) is pushed into a wedge-shaped interspace between the one of the slider elements (79) and a winding element (10).
 8. The method according to claim 5, characterized in that the clamping force (FK) is transmitted between two winding elements (10) by way of an oblique plane which is not oriented radially with respect to an axis of rotation.
 9. The method according to claim 1, characterized in that, between all immediately adjacent rod sections (13, 15) which are arranged in a circumferentially adjacent recess (29) of an inner tool part (23) or in a recess (30) of an outer tool part (36) with a constant separation with respect to an axis of rotation (36), in each case one slider (70) simultaneously effects a clamping force (FK) on immediately adjacent rod sections (13, 15) and thereby an entirety of all the winding elements (10) against one another are removed from the setting tool (20) by an intermediary of the sliders (70) and are then inserted into grooves of an electromagnetically excitable core (11).
 10. The method according to claim 3, characterized in that the sliders (70) are pushed between multiple winding elements (10) by a rotatable slotted guide.
 11. The method according to claim 10, characterized in that one of the slider elements (79) exerts both a clamping force (FK) in the circumferential direction on a winding element (10) and a radial force (FR) in a radial direction on a winding element (10).
 12. The method according to claim 11, characterized in that the one of the slider elements (79) first exerts the radial force (FR) in the radial direction and then exerts the clamping force (FK) in the circumferential direction.
 13. The method according to claim 12, characterized in that, for the purpose of effecting the clamping force (FK) in the circumferential direction, the slider element (78) is pushed into a wedge-shaped interspace between the one of the slider elements (79) and a winding element (10).
 14. The method according to claim 13, characterized in that the clamping force (FK) is transmitted between two winding elements (10) by way of an oblique plane which is not oriented radially with respect to an axis of rotation.
 15. The method according to claim 14, characterized in that, between all immediately adjacent rod sections (13, 15) which are arranged in a circumferentially adjacent recess (29) of an inner tool part (23) or in a recess (30) of an outer tool part (36) with a constant separation with respect to an axis of rotation (36), in each case one slider (70) simultaneously effects a clamping force (FK) on immediately adjacent rod sections (13, 15) and thereby an entirety of all the winding elements (10) against one another are removed from the setting tool (20) by an intermediary of the sliders (70) and are then inserted into grooves of an electromagnetically excitable core (11). 